The synchronization of a fractional order hyperchaotic system based on passive control

This paper investigates the synchronization of a fractional order hyperchaotic system using passive control. A passive controller is designed, based on the properties of a passive system. Then the synchronization between two fractional order hyperchaotic systems under different initial conditions is realized, on the basis of the stability theorem for fractional order systems. Numerical simulations and circuitry simulations are presented to verify the analytical results.     

含有偏置电压源的非齐次分数阶忆阻混沌电路动力学分析与实验研究

物理忆阻器具有不对称的紧磁滞回线,为了更加简便地模拟物理忆阻器的不对称紧磁滞曲线,本文提出了一种含有偏置电压源的分数阶二极管桥忆阻器模型,其具有可连续调控磁滞回线的能力.首先,结合分数阶微积分理论,建立了含有偏置电压源的二极管桥忆阻器的分数阶模型,并对其电气特性进行分析.其次,将其与Jerk混沌电路相融合,建立了含有偏置电压源的非齐次分数阶忆阻混沌电路模型,研究了偏置电压对其系统动态行为的影响.再次,在PSpice中搭建了分数阶的等效电路模型,并对其进行电路仿真验证,实验结果与数值仿真基本一致.最后,在Lab VIEW中完成了电路实验,验证了理论分析的正确性与可行性.结果表明,含有偏置电压源的分数阶忆阻器,可以通过调控偏置电压源的电压,连续获得不对称紧磁滞回线.随着偏置电源电压的改变,非齐次分数阶忆阻混沌系统由于对称性的破环,表现出由倍周期分岔进入混沌的行为.     

Dynamic analysis and fractional-order adaptive sliding mode control for a novel fractional-order ferroresonance system

Ferroresonance is a complex nonlinear electrotechnical phenomenon, which can result in thermal and electrical stresses on the electric power system equipments due to the over voltages and over currents it generates. The prediction or determination of ferroresonance depends mainly on the accuracy of the model used. Fractional-order models are more accurate than the integer-order models. In this paper, a fractional-order ferroresonance model is proposed. The influence of the order on the dynamic behaviors of this fractional-order system under different parameters n and F is investigated.Compared with the integral-order ferroresonance system, small change of the order not only affects the dynamic behavior of the system, but also significantly affects the harmonic components of the system. Then the fractional-order ferroresonance system is implemented by nonlinear circuit emulator. Finally, a fractional-order adaptive sliding mode control(FASMC)method is used to eliminate the abnormal operation state of power system. Since the introduction of the fractional-order sliding mode surface and the adaptive factor, the robustness and disturbance rejection of the controlled system are enhanced. Numerical simulation results demonstrate that the proposed FASMC controller works well for suppression of ferroresonance over voltage.     

Modeling and dynamics analysis of the fractional-order Buck—Boost converter in continuous conduction mode

In this paper,the fractional-order mathematical model and the fractional-order state-space averaging model of the Buck-Boost converter in continuous conduction mode(CCM) are established based on the fractional calculus and the Adomian decomposition method.Some dynamical properties of the current-mode controlled fractional-order Buck-Boost converter are analysed.The simulation is accomplished by using SIMULINK.Numerical simulations are presented to verify the analytical results and we find that bifurcation points will be moved backward as α and β vary.At the same time,the simulation results show that the converter goes through different routes to chaos.     

A hyperchaotic system stabilization via inverse optimal control and experimental research

In this paper, some basic dynamical properties of a four-dimensional autonomous hyperchaotic system are investigated by means of Poincar′e mapping, Lyapunov exponents and bifurcation diagram. The dynamical behaviours of this new hyperchaotic system are proved not only by performing numerical simulation and brief theoretical analysis but also by conducting an electronic circuit experiment. An efficient approaching is developed for global asymptotic stabilization of this four-dimensional hyperchaotic system. Based on the method of inverse optimal control for nonlinear systems, a linear state feedback is electronically implemented. It is remarkably simple as compared with other chaos control ways, like nonlinear state feedback.